CN111238229A - Continuous discharging system of zirconium core sintering tunnel kiln - Google Patents

Abstract

The utility model provides a continuous ejection of compact system of zirconium core sintering tunnel cave, replaces artifically through automatic discharging device and the automatic device of putting things in good order of the ejection of compact, accomplishes the work such as finished product zirconium core takes out and the automatic of finished product zirconium core is put in good order from the tunnel cave, reduces personnel's configuration in the whole operation, can also avoid the safety risk that manual operation exists when improving operating efficiency.

Description

Continuous discharging system of zirconium core sintering tunnel kiln

Technical Field

The invention relates to the technical field of zirconium core sintering tunnel kilns, in particular to a continuous discharging system of a zirconium core sintering tunnel kiln.

Background

The tunnel kiln is a kiln similar to a tunnel and internally provided with delivery vehicles such as kiln cars and the like, built by refractory materials, heat insulation materials and building materials, and is modern continuous-firing thermal equipment. The existing zirconium core sintering tunnel kiln needs to be equipped with workers at the outlet position of the tunnel kiln when production is carried out, manual zirconium core discharging is completed, the overall operation efficiency is low, the large-batch production line production mode cannot be adapted, conditions such as burn and scald are easily generated in the high-temperature operation environment of the discharging side, and safety risks to certain degree exist for operators.

Disclosure of Invention

In order to solve the problems, the continuous discharging system of the zirconium core sintering tunnel kiln provided by the invention replaces manpower with the automatic discharging device and the automatic discharging stacking device to complete the operations of taking out the finished zirconium cores from the tunnel kiln, automatically stacking the finished zirconium cores and the like, so that the configuration of personnel in the whole operation is reduced, the operation efficiency is improved, and the safety risk of manual operation can be avoided.

The technical scheme adopted by the invention for solving the technical problems is as follows: the invention relates to a continuous discharging system of a zirconium core sintering tunnel kiln, which comprises a kiln car, wherein rolling wheels are arranged at the bottom of the kiln car, a transfer box is arranged at the top of the kiln car, the continuous discharging system also comprises an automatic discharging device positioned at the rear end of the tunnel kiln, an automatic discharging stacking device is arranged at the rear side of the automatic discharging device, the automatic discharging device comprises a transverse moving frame, a track matched with the rolling wheels is arranged at the upper side of the transverse moving frame, a first transverse moving slide matched with the transverse moving frame is arranged at the lower side of the transverse moving frame, a reciprocating device is arranged at one side position of the first transverse moving slide and comprises a first fixed seat and a first hydraulic cylinder, one end of the first hydraulic cylinder is arranged on the first fixed seat, the other end of the first hydraulic cylinder is arranged on the transverse moving frame, a kiln car transfer track is arranged at the front side of the reciprocating device, and the kiln, a material taking device is arranged on the other side of the first transverse moving slide way, the material taking device comprises a transverse moving base, a second transverse moving slide way is arranged on the lower portion of the transverse moving base in a matched mode, a second fixing seat is arranged on one side, away from the first transverse moving slide way, of the second transverse moving slide way, a second hydraulic cylinder is arranged between the second fixing seat and the transverse moving base, two mounting grooves are formed in the transverse moving base in parallel, a first supporting rod and a second supporting rod are hinged in each mounting groove, the top ends of the first supporting rod and the second supporting rod in the same mounting groove are hinged to the same inserting rod, slots matched with the two inserting rods are formed in the bottom of the transfer box, a connecting rod is further fixedly arranged between the two second supporting rods, a third hydraulic cylinder is arranged in each mounting groove, one end of the third hydraulic cylinder is hinged in the mounting groove, the other end of the third hydraulic, the lower part of the rotary roller is provided with a motor connected with a rotating shaft of the rotary roller;

the automatic discharging stacking device comprises a transportation base, wherein an active rotary roller is installed on the transportation base, a conveyor belt is arranged at the rear side of the transportation base, a limiting plate is vertically installed at one end, away from the transportation base, of the conveyor belt, a fixed supporting leg is arranged at each of two side positions of the conveyor belt, at least two slide bars are horizontally installed between the two fixed supporting legs, the slide bars penetrate through the conveyor belt, a movable plate is installed on the slide bars in a matched mode, a wood loading plate is installed on the movable plate, a fourth hydraulic cylinder is arranged between one fixed supporting leg and the movable plate, one end of the fourth hydraulic cylinder is fixed on the fixed supporting leg, the other end of the fourth hydraulic cylinder is fixedly connected with the movable plate, a mounting seat is arranged between the conveyor belt and the fixed supporting leg at one side of the fourth hydraulic cylinder, a fifth hydraulic cylinder is horizontally installed, the driving roller on the transportation base can be butted with the roller on the transverse moving base.

Furthermore, a baffle is arranged at the front end of the transverse moving frame on the automatic discharging device and is positioned on the front side of the track. Furthermore, a positioning seat is arranged between the first transverse moving slide way and the second transverse moving slide way on the automatic discharging device, and rubber pads are arranged on two side faces of the positioning seat. Furthermore, an automatic transfer device is arranged in a transverse moving frame on the automatic discharging device, the automatic transfer device comprises a folded plate fixedly arranged at the front side of the transverse moving frame, through holes are formed in the two ends of the upper side of the folded plate, a second slide rod is arranged in the through holes in a matched mode, a second limit baffle is fixedly arranged at one end, away from the kiln car, of the second slide rod, a second push plate is fixedly arranged at the other end of the second slide rod, a spring is arranged between the second push plate and the folded plate, the spring always tends to enable the second push plate to be away from the folded plate, a push plate locking device is further arranged on one side of the folded plate, the push plate locking device comprises a locking plate fixedly connected with the folded plate, a third mounting groove is formed in the locking plate, a stop block is arranged in the third mounting groove and fixed in the third mounting groove through a rotating shaft, a torsion spring is arranged on the rotating shaft, and an unlocking block is arranged on the first transverse moving slideway corresponding to the other end position of the stop block extending out of the third mounting groove, and the unlocking block is fixedly mounted on the first transverse moving slideway through a vertical rod. Furthermore, a movable plate on the automatic discharging stacking device is provided with a clamping block matched with the bottom of the loading wood board.

The invention has the positive effects that: the invention relates to a continuous discharging system of a zirconium core sintering tunnel kiln, wherein an automatic discharging device replaces manpower with a material taking device and a reciprocating device to complete material taking of finished zirconium cores and transfer of kiln cars after kiln discharge, an automatic discharging stacking device transfers sintered zirconium cores to a conveying belt one by one through a driving roller, the zirconium cores are pushed down onto a loading wood board through a push plate after the number of the zirconium cores on the conveying belt meets requirements, the loading wood board is extended out with the same width as that of the loaded zirconium cores in the pushing process to ensure that the zirconium cores are returned and arranged in order to uniformly fall onto the loading wood board in the period so as to be convenient for subsequent transfer or transportation, the device can reduce personnel allocation in the whole operation, replace the traditional manual transportation, avoid the safety risk of manual operation while saving labor force, and ensure that the whole zirconium core sintering operation is more suitable for batch operation of an assembly line, greatly reduces the production cost and improves the production efficiency.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic three-dimensional structure of the automatic discharging device;

FIG. 3 is a front view of FIG. 2;

FIG. 4 is a sectional view taken along line C-C of FIG. 3;

FIG. 5 is a sectional view taken along line D-D of FIG. 4;

FIG. 6 is a schematic view showing a state where the transfer case is picked up by the insert lever;

FIG. 7 is a schematic view of the insertion rod placing the transfer case onto the roller;

FIG. 8 is a schematic three-dimensional structure of the automatic stacking device for discharging materials;

FIG. 9 is a front view of FIG. 8;

FIG. 10 is a top view of FIG. 9;

FIG. 11 is a sectional view taken along line G-G in FIG. 10;

FIG. 12 is a schematic view showing a state where the automatic discharging stacking apparatus stacks a row of zirconium cores;

FIG. 13 is a schematic view showing a state where two rows of zirconium cores are stacked by the automatic stacking apparatus for discharging.

In the figure, 1, a kiln car 2 comprises rolling wheels 3, a transfer box 4, a transverse frame 5 track 6, a first transverse slideway 7, a first fixed seat 8, a first hydraulic cylinder 9, a transverse base 10, a second transverse slideway 11, a second fixed seat 12, a second hydraulic cylinder 13, a mounting groove 14, a first strut 15, a second strut 16, an insertion rod 17, a slot 18, a connecting rod 19, a third hydraulic cylinder 20, a roller 21, a motor 22, a baffle 23, a positioning seat 24, a rubber pad 25, a kiln car transfer track 30 transport base 31, a driving roller 32, a conveyor belt 33, a fixed leg 34, a sliding rod 35, a movable plate 36, a loading wood plate 37, a fourth hydraulic cylinder.

Detailed Description

The invention relates to a continuous discharging system of a zirconium core sintering tunnel kiln, which comprises a kiln car 1, wherein the bottom of the kiln car 1 is provided with a rolling wheel 2, the rolling wheel 2 can be matched with a slide rail in the tunnel kiln to slide, the top of the kiln car 1 is provided with a transfer box 3, a zirconium core is placed in the transfer box 3, and the kiln car 1 is used as a carrier to transport the zirconium core into the tunnel kiln for sintering operation. As shown in fig. 1, the continuous discharging system of the zirconium core sintering tunnel kiln further comprises an automatic discharging device located at the rear end of the tunnel kiln, an automatic discharging stacking device is arranged at the rear side of the automatic discharging device, and the automatic discharging device and the automatic discharging stacking device replace manual work to complete operations such as taking out finished zirconium cores from the tunnel kiln and automatically stacking finished zirconium cores.

As shown in fig. 2 and 3, the automatic discharging device comprises a traverse frame 4 arranged at the exit of the tunnel kiln, a track 5 matched with the rolling wheels 2 is arranged on the upper side of the traverse frame 4, and the track 5 is butted with the track in the tunnel kiln so as to facilitate the kiln car 1 to fall on the traverse frame 4 after being taken out of the kiln.

The lower side of the transverse moving frame 4 is provided with a first transverse moving slide 6 matched with the transverse moving frame, a reciprocating moving device is installed at one side position of the first transverse moving slide 6 and comprises a first fixing seat 7 and a first hydraulic cylinder 8, one end of the first hydraulic cylinder 8 is installed on the first fixing seat 7, and the other end of the first hydraulic cylinder 8 is installed on the transverse moving frame 4. The kiln car transfer rail 25 is arranged on the front side of the reciprocating device, the kiln car transfer rail 25 can be butted with the rail 5, the movement of the transverse moving frame 4 on the first transverse moving slide 6 is completed through the extension and retraction of the first hydraulic cylinder 8, the kiln car 1 which is taken out of the kiln is further transferred to the kiln car transfer rail 25 from a tunnel kiln opening, the transverse moving frame 4 is reset to the front of the tunnel kiln to continuously receive the next kiln car 1 which is about to be taken out of the kiln, wherein the kiln car 1 can be moved to the kiln car transfer rail 25 from the rail 5 through the transfer device, the transfer device can be an existing gantry crane, a hydraulic cylinder or an electric push rod, and the kiln car 1 is provided with labyrinth refractory bricks to play a heat insulation role, so that the temperature of the kiln car 1 is not very high, and the kiln car 1 can also be pushed to the kiln car transfer rail 25 manually.

A material taking device is installed on the other side of the first transverse moving slide 6 so as to take down finished zirconium cores discharged from the kiln and transfer the finished zirconium cores to a discharging automatic stacking device, the material taking device comprises a transverse moving base 9, a second transverse moving slide 10 is arranged on the lower portion of the transverse moving base 9 in a matched mode, a second fixing seat 11 is installed on one side, away from the first transverse moving slide 6, of the second transverse moving slide 10, a second hydraulic cylinder 12 is installed between the second fixing seat 11 and the transverse moving base 9, and the second hydraulic cylinder 12 can stretch out and draw back to drive the transverse moving base 9 to move on the second transverse moving slide 10. As shown in fig. 4, two mounting grooves 13 are formed in the transverse moving base 9 side by side, as shown in fig. 5, each mounting groove 13 is internally hinged with a first supporting rod 14 and a second supporting rod 15, the top ends of the first supporting rod 14 and the second supporting rod 15 in the same mounting groove 13 are hinged with the same inserted rod 16, the bottom of the transfer box 3 is provided with a slot 17 matched with the two inserted rods 16, and the inserted rods 16 can extend into the slot 17 to lift the transfer box 3 so as to take the transfer box 3 down on the kiln car 1. A connecting rod 18 is further fixedly arranged between the two second supporting rods 15 so as to ensure that the second supporting rods 15 and the inserting rods 16 on the two sides rotate synchronously. And a third hydraulic cylinder 19 is arranged in each mounting groove 13, one end of the third hydraulic cylinder 19 is hinged in the mounting groove 13, the other end of the third hydraulic cylinder 19 is hinged on the second supporting rod 15 and used for providing power for the rotation of the second supporting rod 15, and the third hydraulic cylinders 19 on the two sides also keep synchronous extension and retraction to prevent the supporting rods from being twisted in the rotation process.

The upper part of the transverse moving base 9 is also provided with a rotating roller 20, the lower part of the rotating roller 20 is provided with a motor 21 connected with a rotating shaft thereof, as shown in fig. 4, an output shaft of the motor 21 is connected with the rotating shaft of the rotating roller 20 through a conveying belt to drive the rotating roller 20 to rotate, the rotating roller 20 can also be provided with two belt pulleys, and the adjacent rotating rollers 20 at the two sides thereof are provided with the conveying belts through different belt pulleys for transmission. The insertion rod 16 is placed on the roller 20 after the transfer box 3 is removed, and then is transferred to the automatic stacking device for discharging.

When the automatic discharging device works, the first hydraulic cylinder 8 extends out, the traverse frame 4 is positioned at the bottom of a kiln outlet of the tunnel kiln, after a section of kiln car 1 and a zirconium core on the kiln car are sintered from the tunnel kiln, the rolling wheel 2 at the bottom of the kiln car 1 moves to the track 5 on the traverse frame 4, then the third hydraulic cylinder 19 retracts to drive the second support rod 15 to rotate anticlockwise in the direction shown in figure 3 until the insertion rod 16 and the slot 17 at the bottom of the transfer box 3 are positioned at the same horizontal position, the second hydraulic cylinder 12 extends out to drive the traverse base 9 to move towards the kiln car 1, after the insertion rod 16 extends into the slot 17, the third hydraulic cylinder 19 extends out to drive the second support rod 15 to rotate clockwise in the direction shown in figure 3, meanwhile, the second hydraulic cylinder 12 retracts to drive the traverse base 9 to be far away from the kiln car 1, as shown in figure 6, at this time, the state that the insertion rod 16 lifts the transfer box 3 up and takes it off the kiln car 1, and then the third hydraulic cylinder 19 continues to extend until the inserted rod 16 is lowered into the mounting groove 13 below the rotary roller 20, as shown in fig. 7, at this time, the transfer box 3 is lowered onto the rotary roller 20 and can enter the automatic stacking device for discharging under the driving of the rotary roller 20. After the transfer box 3 is taken down from the kiln car 1, the first hydraulic cylinder 8 is retracted to drive the transverse moving frame 4 and the kiln car 1 with the upper part completing material taking to be far away from the kiln outlet, then the kiln car 1 with the material taking completed is pushed to the kiln car transfer track 25 on the transverse moving frame 4 through the transfer device, and the first hydraulic cylinder 8 extends out to push the non-loaded transverse moving frame 4 back to the lower position of the kiln outlet again to receive the next kiln car 1 to be taken out of the kiln.

As shown in fig. 8 and 9, automatic stacking device of ejection of compact is including transporting base 30, transport base 30 is last to install initiative and changes roller 31, as shown in fig. 10, rear side at transporting base 30 is equipped with conveyer belt 32, conveyer belt 32 keeps away from the vertical limiting plate 37 of installing of one end of transporting base 30, wherein conveyer belt 32 is passive rotation, initiative is changeed roller 31 and is responsible for shifting finished product zirconium core on it to conveyer belt 32, finished product zirconium core then can promote conveyer belt 32 to rotate one by one and then finally be located conveyer belt 32, the setting of limiting plate 37 then can guarantee that the finished product zirconium core that is located on conveyer belt 32 can not take place to break away from with conveyer belt 32.

As shown in fig. 9, two side positions of the conveyor belt 32 are respectively provided with a fixed leg 33, at least two sliding rods 34 are horizontally installed between the two fixed legs 33, as shown in fig. 11, the sliding rods 34 penetrate between the conveyor belts 32, movable plates 35 are installed on the sliding rods 34 in a matching manner, loading boards 36 are installed on the movable plates 35, the movable plates 35 and the loading boards 36 are both located between the conveyor belts 32, the loading boards 36 are used for containing finished zirconium cores, and the loading boards 36 can extend out of one side of the conveyor belt 32 along with the movable plates 35 so as to receive the finished zirconium cores falling from the conveyor belt 32.

As shown in fig. 8 and 10, a fourth hydraulic cylinder 38 is disposed between one of the fixed legs 33 and the movable plate 35, one end of the fourth hydraulic cylinder 38 is fixed to the fixed leg 33, the other end of the fourth hydraulic cylinder 38 is fixedly connected to the movable plate 35, and the movable plate 35 is driven by the expansion and contraction of the fourth hydraulic cylinder 38 to move between the conveyor belts 32. A mounting base 39 is arranged between the conveyor belt 32 on the side where the fourth hydraulic cylinder 38 is mounted and the fixed supporting leg 33, a fifth hydraulic cylinder 40 is horizontally mounted on the mounting base 39, a piston rod of the fifth hydraulic cylinder 40 is provided with a push plate 41, the push plate 41 is perpendicular to the movable plate 35, and the push plate 41 is located on the upper side of the conveyor belt 32 and used for pushing the finished zirconium cores on the conveyor belt 32 to the wood loading plate 36. The driving roller 31 on the transport base 30 can be butted with the roller 20 on the traverse base 9.

When the automatic discharging stacking device operates, the finished zirconium cores are conveyed to the conveyor belt 32 by the driving rotary roller 31 on the conveying base 30, because the conveyor belt 32 rotates passively, the subsequent finished zirconium cores push against the finished zirconium cores on the front side one by one to be all located on the conveyor belt 32, the fourth hydraulic cylinder 38 extends to drive the movable plate 35 and the loading wood plate 36 to extend out of the conveyor belt 32 by the width of one finished zirconium core, when the finished zirconium core on the front side touches the limiting plate 37, as shown in fig. 12, the fifth hydraulic cylinder 40 extends out, the push plate 41 pushes the finished zirconium core on the conveyor belt 32 onto the loading wood plate 36, after a row of finished zirconium cores fall onto the loading wood plate 36, the fourth hydraulic cylinder 38 extends out continuously to drive the loading wood plate 36 to extend out of the conveyor belt 32 by the width of the two finished zirconium cores, the fifth hydraulic cylinder 40 retracts to the original position, the driving rotary roller 31 continues to transfer the finished zirconium cores to the conveyor belt 32, as shown in fig. 13, the above operations are repeated to push the finished zirconium cores onto the loaded wood boards 36 until the loaded wood boards 36 are full of the finished zirconium cores, and then the finished zirconium cores are transferred and stored by a forklift or other carrying mechanism, and then the unloaded loaded wood boards 36 are placed on the movable plate 35, the fourth hydraulic cylinder 38 is retracted to the original position, the loaded wood boards 36 are positioned between the conveyor belts 32 again, and the stacking operation of the next loaded wood boards 36 is started. During the operation process of pushing the finished zirconium core, the finished zirconium core is also stacked, returned and arranged, so that the finished zirconium core can be neatly dropped on the loading wood board 36 according to the requirement.

Further, a baffle plate 22 is installed at the front end of the traverse frame 4, and the baffle plate 22 is positioned at the front side of the track 5, so that the kiln car 1 taken out of the kiln can be conveniently positioned and prevented from sliding out of the traverse frame 4.

Furthermore, a positioning seat 23 is arranged between the first transverse moving slide 6 and the second transverse moving slide 10, rubber pads 24 are mounted on two side faces of the positioning seat 23, the positioning seat 23 can limit the transverse moving frames 4 and the transverse moving bases 9 on two sides, it is ensured that the transverse moving frames 4 move to the lower position of the kiln outlet, the transverse moving bases 9 move to the position where the insertion rods 16 can pick up the transfer box 3, meanwhile, the rubber pads 24 on two side faces of the positioning seat 23 can prevent the transverse moving frames 4 and the transverse moving bases 9 from being in hard contact with the positioning seat 23 in the moving process, and the service life of the transverse moving frames can be prolonged.

Further, in order to prevent the push plate 41 from pushing the loading wood board 36 out of the movable plate 35 by a certain distance when pushing the finished zirconium core to fall onto the loading wood board 36, and prevent the loading wood board 36 from being stacked unevenly, the movable plate 35 is provided with a clamping block 42 matched with the bottom of the loading wood board 36, so that the loading wood board 36 and the movable plate 35 do not move relatively in the pushing process of the finished zirconium core, and the stacking evenness of the zirconium core on the loading wood board 36 is further ensured.

The technical solution of the present invention is not limited to the scope of the embodiments of the present invention. The technical contents not described in detail in the present invention are all known techniques.

Claims (4)

1. The utility model provides a continuous ejection of compact system of zirconium core sintering tunnel cave, includes kiln car (1), and the bottom installation of kiln car (1) rolls wheel (2), and the top installation of kiln car (1) shifts case (3), its characterized in that: the automatic discharging device comprises a transverse moving frame (4), a track (5) matched with the rolling wheels (2) is installed on the upper side of the transverse moving frame (4), a first transverse moving slide (6) matched with the transverse moving frame is arranged on the lower side of the transverse moving frame (4), a reciprocating moving device is installed at one side position of the first transverse moving slide (6) and comprises a first fixing seat (7) and a first hydraulic cylinder (8), one end of the first hydraulic cylinder (8) is installed on the first fixing seat (7), the other end of the first hydraulic cylinder (8) is installed on the transverse moving frame (4), a kiln car transfer track (25) is arranged on the front side of the reciprocating moving device, and the kiln car transfer track (25) can be butted with the track (5), a material taking device is arranged on the other side of the first transverse moving slide way (6), the material taking device comprises a transverse moving base (9), a second transverse moving slide way (10) is arranged on the lower portion of the transverse moving base (9) in a matched mode, a second fixing seat (11) is arranged on one side, far away from the first transverse moving slide way (6), of the second transverse moving slide way (10), a second hydraulic cylinder (12) is arranged between the second fixing seat (11) and the transverse moving base (9), two installation grooves (13) are formed in the transverse moving base (9) side by side, a first supporting rod (14) and a second supporting rod (15) are hinged in each installation groove (13), the top ends of the first supporting rod (14) and the second supporting rod (15) in the same installation groove (13) are hinged to the same inserting rod (16), slots (17) matched with the two inserting rods (16) are formed in the bottom of the transfer box (3), and a connecting rod (18) is, a third hydraulic cylinder (19) is arranged in each mounting groove (13), one end of the third hydraulic cylinder (19) is hinged in the mounting groove (13), the other end of the third hydraulic cylinder (19) is hinged on a second support rod (15), a rotating roller (20) is further mounted on the upper portion of the transverse moving base (9), and a motor (21) connected with a rotating shaft of the rotating roller (20) is arranged on the lower portion of the rotating roller;

the automatic stacking device for the discharged materials comprises a transportation base (30), wherein a driving rotary roller (31) is installed on the transportation base (30), a conveyor belt (32) is arranged on the rear side of the transportation base (30), a limiting plate (37) is vertically installed at one end, far away from the transportation base (30), of the conveyor belt (32), fixed support legs (33) are arranged at positions on two sides of the conveyor belt (32), at least two slide bars (34) are horizontally installed between the two fixed support legs (33), the slide bars (34) penetrate through the conveyor belt (32), a movable plate (35) is installed on the slide bars (34) in a matched mode, a loading wood plate (36) is installed on the movable plate (35), a fourth hydraulic cylinder (38) is arranged between one fixed support leg (33) and the movable plate (35), one end of the fourth hydraulic cylinder (38) is fixed on the fixed support leg (33), and the other end of the fourth hydraulic cylinder (38, the conveying device is characterized in that a mounting seat (39) is arranged between the conveying belt (32) and the fixed supporting legs (33) on one side of the fourth hydraulic cylinder (38), a fifth hydraulic cylinder (40) is horizontally mounted on the mounting seat (39), a push plate (41) is arranged on a piston rod of the fifth hydraulic cylinder (40), the push plate (41) is perpendicular to the movable plate (35), and the driving rotary roller (31) on the conveying base (30) can be in butt joint with the rotary roller (20) on the transverse moving base (9).

2. The continuous discharging system of the zirconium core sintering tunnel kiln as claimed in claim 1, wherein: a baffle (22) is installed at the front end of the transverse moving frame (4) on the automatic discharging device, and the baffle (22) is located on the front side of the track (5).

3. The continuous discharging system of the zirconium core sintering tunnel kiln as claimed in claim 1, wherein: a positioning seat (23) is arranged between the first transverse moving slideway (6) and the second transverse moving slideway (10) on the automatic discharging device, and rubber pads (24) are respectively arranged on two side faces of the positioning seat (23).

4. The continuous discharging system of the zirconium core sintering tunnel kiln as claimed in claim 1, wherein: a movable plate (35) on the automatic discharging stacking device is provided with a clamping block (42) matched with the bottom of the loading wood plate (36).

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